Capital markets. Our next featured company, Regeneron, has always been known for its R&D engine. There is a lot more coming from their pipeline, really, over the next 6 months- 12 months and beyond. The architect of that has been their Board Co-Chair, President, and CSO, George Yancopoulos. We are really pleased to have George with us today. Alongside him on the stage, Mark Hudson, Senior Director of IR for Regeneron. Thanks again for joining us and looking forward to the discussion.
Appreciate your having us. Go ahead, Mark.
Yeah. Before we get started, obviously, I have to read a forward-looking statement. Otherwise, my legal folks will get mad at me. I would like to remind you that remarks made today may include forward-looking statements about Regeneron. Each forward-looking statement is subject to risks and uncertainties that could cause actual results and events to differ materially from those projected in such statement. The description of material risks and uncertainties can be found in Regeneron's SEC filings. Regeneron does not undertake any obligation to update any forward-looking statement, whether as a result of new information, future events, or otherwise. It is a pleasure to be here, Brian. We are glad we have George with us. We will get right into Q&A.
Thanks. Why don't we start with the next upcoming catalyst, Phase 3 data for itepekimab in COPD? Can you tell us what you've learned from the prior data in asthma and COPD about the IL-33 mechanism? How should we be thinking about some of the analyses you've done so far? You mentioned an interim analysis that's been done halfway through this ongoing study. In your view, what does that tell you, how does that inform you about the potential outcome of the study? What are you looking for out of it?
Right. Maybe the first point to make is that I think a lot of people just assume that all antibodies, all antibodies against a particular target, they're all created equally. I think the important point to make is, even in today's world, that's not true. You look at many of our most important medicines, Eylea, Dupilumab, everybody else tried to make an IL-4 receptor antibody, including the biggest companies in the world, like Amgen. They went through clinical trials. They failed in every single Phase 3 trial. We succeeded in 8 out of 8 Phase 3 trials, which is probably a record. Why? It comes down to technology. It comes to understanding biology. It comes down to having the technologies that can maybe predict which setting and why.
What I think that we've shown over the years is that whether it's with soluble receptors like Eylea or whether it's with antibodies like Dupilumab or whether it's bispecifics, we continually have the best-in-class type molecules that have and deliver the best data. Why? Because we spend a lot of time in the labs creating the technologies that give us the best antibodies. We also have these incredible technologies that allow us to choose. Now, most people, they make one antibody, they're happy, and they go with it. Okay. We don't make dozens of antibodies. We don't make hundreds of antibodies. We literally screen millions of antibodies because we were the first people to develop a lot of these technologies. We've created these incredible high-throughput technologies. It starts with the molecule.
All molecules, all IL-33 blockers, all IL-4 blockers, all VEGF blockers, they're not all created equally. We think we have the best molecule here. We've tested it against every existing agent that's out there. That's number one. Number two, as I said, why is it that we've hit on 8 out of 8 Phase 3 trials for Dupixent? We have a cheat code. We built the world's largest DNA sequence-based big data set on the planet where we can see how genetic variation can impact disease variation. Nobody else has the ability in these tools because they didn't invest in the time and the effort and the dollars to build such a resource. As we've shown, for example, for Dupixent, we have the genetics that shows that if you have up activation of the IL-4/13 pathway, that promotes certain diseases.
You are protected if you have the genetics that show that you have low tone in that genetic pathway. We did the same thing with IL-33. One is you start, you create the best possible antibody, screening millions of antibodies using the world's best technologies. Then you use the genetics database that we have that other people do not have to tell us which diseases can this really make an impact in. We have shown a lot of this publicly. The genetics are really pretty strong that in certain diseases, asthma, chronic rhinosinusitis with nasal polyps, and COPD, the genetics suggest that too much of this pathway is associated with more of this disease, less of this genetic pathway, less of this disease.
These are things that we validate over time, that these genetic pathway scores are really good predictors of where you should go with your best-in-class molecules. We've done some of the early studies, as you mentioned. Our asthma data, if you look across the field, other people's molecules that they're going forward in COPD actually failed to show any sort of benefit in asthma. We had pretty much DUPI-like data in asthma. Now in COPD, we've focused on a different subset of patients where the data suggests to us that it could make a difference for these patients and a different subset of patients than the patients that are currently benefiting from Dupixent in COPD.
Tell us a little bit more about that subset. I know it is a little bit different. Maybe there is a little overlap, but it is generally different from what DUPI is now approved for. What would you view as compelling data, just given the lack of options for low eosinophil patients? What are you hoping to see?
I think, as you said, I mean, clearly, Dupixent has changed the field for patients with eosinophilic COPD with over 30% reductions in exacerbations. That is really, obviously, it's unprecedented. No other molecule has delivered anything close to that. We think that in this unmet need population with the low eosinophils, we believe that if we hit a 20% decrease in exacerbations, that can make a really, really big difference for these patients that really right now have very few new kinds of treatments available to them for years.
You talked about antibody design, discovery, leveraging the genetic database as well. To what extent does the additional information from the interim analysis further support your confidence in success here?
Yeah. I think that we haven't disclosed the numbers and so forth. We basically announced that we had included into the program an interim efficacy analysis, which if we didn't meet it, then we would not go forward. It gives us more confidence since we met that hurdle that there's increased chances that the trial would work. If we didn't meet it, we'd have much less chance that the trial is going to work.
Looking forward to those data.
Yes.
On the oncology front, a lot of efforts there as well. You obviously have antibody expertise as well as Libtayo as a strong backbone to build around. You've had some early successes like Linvoseltamab, at least so far, and with Fianlimab. But you've also faced some challenges as well, such as with the PSMA bispecific. Can you talk about which of the oncology assets you're most excited about these days and what approaches are going to be of highest focus over the next few years in the cancer space?
Yeah. I'm excited about the breadth across the portfolio. I think that that's what makes it exciting. Once again, it starts with the best molecules. I mean, you mentioned Libtayo, our PD-1 blocker. As you guys probably know, I mean, there are so many PD-1s out there. There are only two that have met the high bar for efficacy in first-line lung cancer, Libtayo and Keytruda. And arguably, our data now, our long-term data, looks like it's best in class. It's still hard to make the best antibodies. I don't care where you're making them. The data just says right now, there are only two PD-1s that are approved broadly across the first-line lung cancer setting. We have now, for example, shown settings now, for example, in adjuvant cutaneous squamous cell carcinoma where ours is the only molecule that works, where, for example, Keytruda failed.
It's important to start with the best molecules. Same thing you mentioned, our BCMA bispecific for myeloma. We have double the complete response rates of the two competitors out there. That's what it's all about, getting complete responses and remissions. Once again, you start with the best molecules. You also have to figure out creative ways in which to employ them and where to go. There again, we're excited across our portfolio. We're excited that we have what we think are two of the best-in-class checkpoint inhibitors. We're combining our PD-1 Libtayo with our LAG-3 Fianlimab. We're going to be getting Phase 3 data in first-line metastatic melanoma in the second half of this year. I think that that could really make a big difference for patients.
I mean, the field has been looking for advances by combining checkpoint inhibitors since the first checkpoint inhibitors were approved more than 15 years ago, and nobody has yet succeeded. We think this may be the best shot for getting both increased efficacy without dramatically promoting safety issues. We are excited about that. I mentioned, we also think we have the best-in-class bispecifics. They have been validated in terms of producing very impressive data in the last lines of both myeloma or lymphoma, for example. What we are very excited about is moving it into the earlier line settings. We have recently released, and we are going to be talking at ASCO a lot more about how these agents are behaving in earlier lines as monotherapies or as in very restricted combinations. We think that they have the real opportunity to completely change the field.
If you guys know the treatment paradigm for myeloma and lymphoma, these are very, very tough, complicated regimens where you're putting together many, many toxic molecules to try to get efficacy. The data suggests that our bispecific, either alone or with dual combinations, can actually produce better data and hopefully more safely in the long run. Moving our bispecifics to earlier stages, even moving to premalignant disease, we think that these agents are so well tolerated and so safe in comparison to traditional chemotherapy that we think we can go into premalignant settings and, for example, cure precursor conditions that ultimately lead, for example, to myeloma. These are really, really exciting opportunities where you can start imagining treating cancer more by prevention than by waiting to get a serious advanced cancer and then having to treat the very serious advanced cancer.
I mean, I can see a future world just like everybody gets tested for their cholesterol and gets put on lipid-lowering therapies, hopefully PCSK9 blockers. I can see the same thing, for example, a very substantial proportion of the population over the age of 60 has what you call monoclonal gammopathy of unknown significance, which has a very significant, a few percent a year rate of transforming to myeloma, which even in the setting with bispecifics and CAR-Ts is still relatively incurable. We can imagine sending up, taking all those patients and essentially short-term treatment, clearing the precursor conditions so they have no risk of developing disease. These, I think, having these best-in-class molecules across so many different settings, I think opens up a lot of opportunities for doing things and going into spaces where people have not even imagined going before.
That's really fascinating. I know that's something they're looking at in Alzheimer's disease as well. It seems to be a concept we could see more and more of, especially if you have a safe enough agent. Just on the Fianlimab melanoma data that you mentioned, what do you think is the biggest differentiator that's kind of led to some of the data that you've, advantages you've seen so far? Is it the better LAG-3 or the better PD-1 backbone? As a second-to-market agent, what do you think you need to show to gain the most commercial traction?
Yeah. As I was saying before, especially in cancer, you do not want to be going in with two inferior agents and combining them and hoping that they combine and do a little bit better than the agents individually. You want to go with the best-in-class agent. We think it really matters that you go in with the best PD-1 and with the best LAG-3. Hope and the early data that we have now seen prior to our Phase 3 suggests that putting two of the best-in-class checkpoint inhibitors for these checkpoint pathways, the PD-1 and LAG-3, really can produce better data. We were seeing in the early studies 50%-60% response rates as opposed to 40% response rates with the combo of the competitors, with much longer control of disease doubling in terms of time frame.
If we get anywhere near that data, I think that this is obviously game-changing for these first-line metastatic melanoma patients. We can only hope for their sake that the data really at all comes close to resembling that sort of data. It would be transformational, obviously. The other good news about it, so far in the studies, is that we have very good safety profiles. Once again, I think it has to do a lot with the design of the molecules and how you screen for them and so forth. You do not just go with the one antibody you have. You have a variety of screens that let you go through thousands or millions to get the best-in-class agents.
Right now, the data suggests that there's a real opportunity that this can really take treatment of this terrible cancer to a whole nother level, both in terms of the efficacy, but also with a very desirable safety profile.
Okay. Great. Shifting gears a bit, we've been getting asked more and more about the Factor XIs. It seems like people have started to take notice. You've had some initial proof of concept data there. You've taken a different approach, having two different—you've taken the antibody route and two different antibodies. What were some of the learnings from maybe the prior efforts in the Factor XI space that you were able to draw from in designing this pathway that you're going after? What are your plans going forward? Are you planning to look at higher-risk patients, go broad on lower risk in patients who would otherwise be eligible for factor Xs? How should we foresee the Phase 3 program kind of taking shape? I know it's going to be kicking off pretty soon.
Those are great questions. I think the way we look at it is that one can stop blood clot formation cold, okay? When you do that with traditional approaches up until now, the problem is you unfortunately cause a lot of bleeding. This is why anticoagulation therapy is not as widely used as it could be used if it was safe. It is all about the bleeding. That is what it is all about. It is not about making a better anticoagulant that can stop clotting better. It is about doing it more safely so you do not have to worry about a brain bleed or other significant bleeds. I know I struggle with this with my dad. He had atrial fibrillation, and he went on anticoagulants, and he was bleeding all over the place. He goes, "I am not taking this.
The bleeding is going to kill me." Patients do not like to see bruises and blood all over themselves. God forbid they have a fall and they have a really bad bleed, and they realize and recognize that this may be a greater risk to me than the clot is, which I cannot see. That is the other thing, you are seeing a lot of this bleeding. That is the thing that we are focused on. That is why we have developed two antibodies. That is what is different from the small molecules and the factor Xs and all that. Once again, going back to our large genetics databases, it suggests that the factor XI pathway may be able to approach, if not meet, the sort of anticoagulation and coagulation control that you can get with the factor Xs or other approaches, but much, much more safely.
It all depends, I think, more than on the efficacy. We've demonstrated, as you said, in our early studies, efficacy that, as I said, is approaching, if not comparable to that of existing agents. If the data continues to support the genetics evidence that suggests that this could be a much safer approach, you can imagine, once again, something akin to putting this—I'm not saying literally—but like putting in the drinking water. If you could stop clotting safely with minimal risk of bleeding, many, many more people should take it. Right now, these are limited to the higher-risk situations because of the bleeding risk. You have to balance, "Oh, yeah, I want to prevent the clot, but I don't want to kill somebody or cause a lot of problems from the bleeding." That limits the use of these.
We think the safety profile is going to determine how broadly these can be used and across what populations. I'm sure we've all seen. You go to the hospital, you're at increased risk for clot. Okay, what do they do? They put these cuffs. You ever visit any family members? The cuffs aren't on. They're not working, whatever. People aren't being anticoagulated. You could literally argue that a very, very high percentage of the population, as you get older, needs substantial anticoagulation. We know even baby aspirin has its risks. The safer the profile, the more widely it can be used across more and more indications. Of course, we are going into the higher-risk settings, but we also have some ambitions depending on the safety profile of really going much broader into areas that people haven't really ventured before.
Start with higher risk, and then as you get a better sense of whether this is indeed as safe as hoped, go broad?
Yeah. I didn't say start with higher risk. I think that we have two antibodies where we're exploring multiple opportunities simultaneously.
Got it. Regeneron has lots of genetically validated targets coming out of the platform that you've talked a lot about, things like NPR1, GPR75 that we're starting to see advance into clinical development. Can you tell us a little bit more about the Regeneron Genetics Center, some of the key differentiating elements, and really how it's prompted and shaped both your internal pipeline and some of your external collaborations, including this week's acquisition of 23andMe?
Sure. No, great question. We believe nothing else exists like it on the planet. We have invested more than anybody else in terms of building a sequence-based big data set. The problem that we have recognized, and I hope everybody recognizes, is you cannot count on the published literature. Some number of it, 70%, 80%, 90% of it is either wrong or misleading. There are not that many other resources out there that you can use. I do not even read the literature anymore. I want to know whether, oh, is the IL-4/IL-13 pathway relevant to eosinophilic esophagitis? I could read 100 papers, half of which say one thing, half of which say the other thing. Or I just go to my database, and my database tells me the truth, okay? People talk about AI like it is going to deliver us some sort of incredible, great opportunities.
The problem is, in our field, if you train AI on the existing data that exists, you're going to get random garbage in, garbage out.
Garbage in, garbage out.
Okay? Garbage in, garbage out. We've taken the time and put in both the time, the incredible scientists and technology, and the investments to build what we think is the most valuable big data set in our industry. That is something that literally will empower machine learning and other approaches. That's what we use all the time. Like I said, we want to understand which pathway and which disease and so forth. We can get definitive answers from our genetics data set. We've made about a little bit more than 10% of it public. We're the ones, for example, who sequenced and made public the UK Biobank data set. That is outside of Regeneron, and that's the most widely used DNA sequence-based data set on the planet. We created that.
We made it public, but it's only a little bit more than 10% of the data that we have. More data is power here. I think this is a huge differentiator for us. As you mentioned, just this week, we announced that we were involved in a process, which we hope will be finalized by the courts and closed in the third quarter, where we're acquiring 23andMe. We think that this is an interesting piece to our puzzle. We've been, we believe, somewhat stealthily the world leaders in DNA sequence and genetic-based research. I do want to remind you, we're probably the first company that bet its entire future on the power of DNA. We've been doing high throughput genetics longer, I believe, better, and certainly faster than anybody else has been doing for over 30 years.
We have been doing it, like I said, for our internal purposes. We think that there is a lot of room to help benefit individual patients' personal health, taking advantage of this information. This was the vision, and this is how and why 23andMe was created. We think that they were created with a great vision and a great brand. They did not necessarily have the best technology. We think that we can help achieve the initial mission and goals of 23andMe to help individuals with their personal health. We think we can go broader than that. We think that this could be a platform that we can use to more broadly impact societal health and well-being by taking advantage of our DNA and genetics approaches. We are going to really be taking, I think, those capabilities, that mission, that dream to a whole nother level.
I mean, the way we think of it is 23 and more.
Great. Maybe just a quick question on DUPI and kind of the longer-term plans. Understanding the field is obviously competitive, and DUPI is pretty tough to improve upon. Broadly speaking, how much of a priority do you have on developing next-generation versions or derivations of DUPI internally or externally thinking that may have certain advantages? Just how do you think about much, much longer-term kind of leveraging the fantastic data set and antibody that you have to go for the next 20, 30 years with it?
We think Eylea is an interesting example. People can continue to debate how the science is going to turn out from a commercial point of view. As many of you may or may not remember, when we first launched Eylea almost 15 years ago, it was clearly like we always do. We delivered the best-in-class molecules that really took over the space because it was the most potent biologic blocking VEGF ever designed. If you guys have followed the industry, there were dozens and dozens of companies that tried to match or take down Eylea over the subsequent 15 years. We can argue about it, but I think that the only people who delivered an agent that delivered clinical data in the label that actually is better than the original Eylea is Regeneron with Eylea HD.
We all know there have been certain hurdles and limitations that are maybe limiting it a little bit commercially. Clearly, the clinical data is the best-in-class data. For 15 years, dozens tried. They all failed to meet or beat Eylea, except for Regeneron. We are using the same types of thinking and approaches and so forth for all the programs that we are working on, whether it is dupilumab or whether it is some of the cancer programs and so forth. We are always trying to take things to the next level. History shows that we have a pretty good track record of doing that. I would hope we would be able to do it with DUPI. It is not just making the DUPI better. It is thinking about maybe more creative ways to use it or use it in special proprietary combinations and so forth and so on.
We built the field, and we fully expect to continue to lead the field for years to come.
On that note, lots more we could cover, but unfortunately, we have to wrap up. George, thank you so much.
Thank you, Brian.
Thank you guys. Really appreciate it.